Related papers: Non-Convex Structured Phase Retrieval

Non-Convex Structured Phase Retrieval

URL: http://arxiv.org/abs/2006.13298v1
Date: Tue, 23 Jun 2020 20:12:40 GMT
Title: Non-Convex Structured Phase Retrieval
Authors: Namrata Vaswani (Iowa State University)
Abstract summary: Phase retrieval (PR) is a problem that occurs in numerous signal and image acquisition domains. Two commonly used structural assumptions are (i) sparsity a given signal/image or (ii) a low rank model on the matrix formed by a set, e.g., a time sequence of signals/images.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Phase retrieval (PR), also sometimes referred to as quadratic sensing, is a problem that occurs in numerous signal and image acquisition domains ranging from optics, X-ray crystallography, Fourier ptychography, sub-diffraction imaging, and astronomy. In each of these domains, the physics of the acquisition system dictates that only the magnitude (intensity) of certain linear projections of the signal or image can be measured. Without any assumptions on the unknown signal, accurate recovery necessarily requires an over-complete set of measurements. The only way to reduce the measurements/sample complexity is to place extra assumptions on the unknown signal/image. A simple and practically valid set of assumptions is obtained by exploiting the structure inherently present in many natural signals or sequences of signals. Two commonly used structural assumptions are (i) sparsity of a given signal/image or (ii) a low rank model on the matrix formed by a set, e.g., a time sequence, of signals/images. Both have been explored for solving the PR problem in a sample-efficient fashion. This article describes this work, with a focus on non-convex approaches that come with sample complexity guarantees under simple assumptions. We also briefly describe other different types of structural assumptions that have been used in recent literature.

Related papers

Machine learning with sub-diffraction resolution in the photon-counting regime [0.0]
spatial-mode demultiplexing (SPADE) has been proposed as a method to achieve sub-Rayleigh estimation. We show that SPADE yields sub-diffraction resolution in the broader context of image classification.
arXiv Detail & Related papers (2024-06-05T12:08:58Z)
Exploring Invariance in Images through One-way Wave Equations [96.90549064390608]
In this paper, we empirically reveal an invariance over images-images share a set of one-way wave equations with latent speeds. We demonstrate it using an intuitive encoder-decoder framework where each image is encoded into its corresponding initial condition.
arXiv Detail & Related papers (2023-10-19T17:59:37Z)
Single-photon sub-Rayleigh precision measurements of a pair of incoherent sources of unequal intensity [0.0]
We consider single-photon imaging of two point-like emitters of unequal intensity. We employ multi-plane light conversion technology to experimentally implement Hermite-Gaussian spatial-mode demultiplexing.
arXiv Detail & Related papers (2023-09-05T14:58:34Z)
Signal Reconstruction from Samples at Unknown Locations with Application to 2D Unknown View Tomography [2.284915385433677]
We prove that reconstruction methods are resilient to a certain proportion of errors in the specification of the sample location ordering. This is the first piece of work to perform such an analysis for 2D UVT and explicitly relate it to advances in sampling theory.
arXiv Detail & Related papers (2023-04-13T10:01:29Z)
Meta-Learning Sparse Implicit Neural Representations [69.15490627853629]
Implicit neural representations are a promising new avenue of representing general signals. Current approach is difficult to scale for a large number of signals or a data set. We show that meta-learned sparse neural representations achieve a much smaller loss than dense meta-learned models.
arXiv Detail & Related papers (2021-10-27T18:02:53Z)
Low-Light Image Enhancement with Normalizing Flow [92.52290821418778]
In this paper, we investigate to model this one-to-many relationship via a proposed normalizing flow model. An invertible network that takes the low-light images/features as the condition and learns to map the distribution of normally exposed images into a Gaussian distribution. The experimental results on the existing benchmark datasets show our method achieves better quantitative and qualitative results, obtaining better-exposed illumination, less noise and artifact, and richer colors.
arXiv Detail & Related papers (2021-09-13T12:45:08Z)
Modulated Periodic Activations for Generalizable Local Functional Representations [113.64179351957888]
We present a new representation that generalizes to multiple instances and achieves state-of-the-art fidelity. Our approach produces general functional representations of images, videos and shapes, and achieves higher reconstruction quality than prior works that are optimized for a single signal.
arXiv Detail & Related papers (2021-04-08T17:59:04Z)
Deep Unfolded Recovery of Sub-Nyquist Sampled Ultrasound Image [94.42139459221784]
We propose a reconstruction method from sub-Nyquist samples in the time and spatial domain, that is based on unfolding the ISTA algorithm. Our method allows reducing the number of array elements, sampling rate, and computational time while ensuring high quality imaging performance.
arXiv Detail & Related papers (2021-03-01T19:19:38Z)
Scale factor point spread function matching: Beyond aliasing in image resampling [4.81150027600776]
Imaging devices exploit the Nyquist-Shannon sampling theorem to avoid both aliasing and redundant oversampling by design. In medical image resampling, images are considered as continuous functions, are warped by a spatial transformation, and are then sampled on a regular grid. This paper shows that this oversight introduces artefacts, including aliasing, that can lead to important bias in clinical applications.
arXiv Detail & Related papers (2021-01-16T11:40:58Z)
Analytic Signal Phase in $N-D$ by Linear Symmetry Tensor--fingerprint modeling [69.35569554213679]
We show that the Analytic Signal phase, and its gradient have a hitherto unstudied discontinuity in $2-D $ and higher dimensions. This shortcoming can result in severe artifacts whereas the problem does not exist in $1-D $ signals. We suggest the use of Linear Symmetry phase, relying on more than one set of Gabor filters, but with a negligible computational add-on.
arXiv Detail & Related papers (2020-05-16T21:17:26Z)
Class-Specific Blind Deconvolutional Phase Retrieval Under a Generative Prior [8.712404218757733]
The problem arises in various imaging modalities such as Fourier ptychography, X-ray crystallography, and in visible light communication. We propose to solve this inverse problem using alternating gradient descent algorithm under two pretrained deep generative networks as priors. The proposed recovery algorithm strives to find a sharp image and a blur kernel in the range of the respective pre-generators that textitbest explain the forward measurement model.
arXiv Detail & Related papers (2020-02-28T07:36:28Z)

This list is automatically generated from the titles and abstracts of the papers in this site.